A new NAD+-dependent opine dehydrogenase from Arthrobacter sp. strain 1C.

A new NAD+-dependent opine dehydrogenase was purified to homogeneity from Arthrobacter sp. strain 1C isolated from soil by an enrichment culture technique. The enzyme has a molecular weight of about 70,000 and consists of two identical subunits with molecular weights of about 36,000. The enzyme catalyzed a reversible oxidation-reduction reaction of opine-type secondary amine dicarboxylic acids. In the oxidative deamination reaction, the enzyme was active toward unusual opines, such as N-[1-R-(carboxyl)ethyl]-S-methionine and N-[1-R-(carboxyl)ethyl]-S-phenylalanine. In the reductive secondary amine-forming reaction with NADH as a cofactor, the enzyme utilized L-amino acids such as L-methionine, L-isoleucine, L-valine, L-phenylalanine, L-leucine, L-alanine, and L-threonine as amino donors and alpha-keto acids such as pyruvate, oxaloacetate, glyoxylate, and alpha-ketobutyrate as amino acceptors. The product enzymatically synthesized from L-phenylalanine and pyruvate in the presence of NADH was identified as N-[1-R-(carboxyl)ethyl]-S-phenylalanine.     

Effects of noncovalent and covalent FAD binding on the redox and catalytic properties of p-cresol methylhydroxylase

Each flavoprotein subunit (alpha or PchF) of the alpha(2)beta(2) flavocytochrome p-cresol methylhydroxylase (PCMH) from Pseudomonas putida contains FAD covalently attached to Tyr384. PCMH oxidizes p-cresol to 4-hydroxybenzyl alcohol, which is oxidized subsequently by PCMH to 4-hydroxybenzaldehyde. The Y384F mutant form of PchF (apo-PchF[Y384F]) displayed stoichiometric noncovalent FAD binding. PchF[Y384F]FAD associated with the cytochrome subunit (beta or PchC) (producing PCMH[Y384F]), although not as avidly as with wild-type PchF containing covalently bound FAD (PchF(C)). Dramatic increases in the two-electron E(m,7) (NHE) values for FAD were observed when it bound noncovalently to either apo-PchF or apo-PchF[Y384F], and the two-electron E(m,7) value for FAD was increased further by about 75 mV upon covalent binding to PchF, i.e., PchF(C). The E(m,7) values increased by approximately 20 and 45 mV, respectively, when PchF(C) and PchF[Y384F]FAD associated with PchC. The two-electron E(m,7) for covalently bound FAD in PCMH is 84 mV, the highest measured for a flavoprotein. The values for the one-electron redox potentials (E(m,7), NHE) for FAD were measured also for various forms of PchF. Under anaerobiosis, the reduction of PchF[Y384F]FAD by substrates was similar to that observed previously for PchF containing noncovalently bound FAD. Stopped-flow kinetic studies indicated a rapid substrate reduction of the FAD and heme in PCMH[Y384F] which produced PchF[Y384F]FAD(rad) x PchC, the mutant enzyme containing the flavin radical and reduced heme. These experiments also revealed a slow reduction of unassociated PchC(ox) by PchF[Y384F]FAD(rad) x PchC. Steady-state kinetic studies of the reaction of PCMH[Y384F] with p-cresol indicated that the K(m) for this substrate was unchanged relative to that of PCMH, but that the k(cat) was diminished by an order of magnitude. The data indicate that the covalent attachment of FAD to PchF assists catalysis by raising the E(m,7) of the flavin. Contributions to this effect likely result from conformational changes.     

Expression and characterization of ferredoxin and flavin adenine dinucleotide binding domains of the reductase component of soluble methane monooxygenase from Methylococcus capsulatus (Bath)

Soluble methane monooxygenase (sMMO) from Methylococcus capsulatus (Bath) catalyzes the selective oxidation of methane to methanol, the first step in the primary catabolic pathway of methanotrophic bacteria. A reductase (MMOR) mediates electron transfer from NADH through its FAD and [2Fe-2S] cofactors to the dinuclear non-heme iron sites housed in a hydroxylase (MMOH). The structurally distinct [2Fe-2S], FAD, and NADH binding domains of MMOR facilitated division of the protein into its functional ferredoxin (MMOR-Fd) and FAD/NADH (MMOR-FAD) component domains. The 10.9 kDa MMOR-Fd (MMOR residues 1-98) and 27.6 kDa MMOR-FAD (MMOR residues 99-348) were expressed and purified from recombinant Escherichia coli systems. The Fd and FAD domains have absorbance spectral features identical to those of the [2Fe-2S] and flavin components, respectively, of MMOR. Redox potentials, determined by reductive titrations that included indicator dyes, for the [2Fe-2S] and FAD cofactors in the domains are as follows: -205.2 +/- 1.3 mV for [2Fe-2S](ox/red), -172.4 +/- 2.0 mV for FAD(ox/sq), and -266.4 +/- 3.5 mV for FAD(sq/hq). Kinetic and spectral properties of intermediates observed in the reaction of oxidized MMOR-FAD (FAD(ox)) with NADH at 4 degrees C were established with stopped-flow UV-visible spectroscopy. Analysis of the influence of pH on MMOR-FAD optical spectra, redox potentials, and NADH reaction kinetics afforded pK(a) values for the semiquinone (FAD(sq)) and hydroquinone (FAD(hq)) MMOR-FAD species and two protonatable groups near the flavin cofactor. Electron transfer from MMOR-FAD(hq) to oxidized MMOR-Fd is extremely slow (k = 1500 M(-1) s(-1) at 25 degrees C, compared to 90 s(-1) at 4 degrees C for internal electron transfer between cofactors in MMOR), indicating that cofactor proximity is essential for efficient interdomain electron transfer.     

Exchange of free and bound coenzyme of flavin enzymes studied with [14C]FAD.

The exchange of bound FAD for free FAD was studied with D-amino acid oxidase (D-amino acid:oxygen oxidoreductase (deaminating), EC 1.4.3.3) and beta-D-glucose oxidase (beta-D-glucose:oxygen 1-oxidoreductase, EC 1.1.3.4). For a simple measurement of the reaction rate, equimolar amounts of the enzyme and [14C]FAD were mixed. The exchange occurred very rapidly in the holoenzyme of D-amino acid oxidase at 25 degrees C, pH 8.3 (half life of the exchange: 0.8 min), but slowly in the presence of the substrate or a competitive inhibitor, benzoate. It also occurred slowly in the purple complex of D-amino acid oxidase. In the case of beta-D-glucose oxidase, however, the exchange occurred very slowly at 25 degrees C, pH 5.6, regardless of the presence of the substrate or p-chloromercuribenzoate. On the basis of these findings, the turnover of the coenzymes of flavin enzymes in mammals is discussed.     

Spectral and kinetic studies on Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating)

Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating) contains two FAD molecules in one molecule of the enzyme (Koyama, H. (1983) J. Biochem. 93, 1313-1319). When the enzyme was mixed anaerobically with L-phenylalanine, beta-2-thienylalanine, L-tyrosine, or L-methionine, a spectral species (purple intermediate) with a broad absorption band around 540 nm was observed with each substrate, and decayed slowly. From the data on the overall reaction kinetics, the rate of the L-phenylalanine oxidase reaction was expressed as follows. e/v = e/Vm + A/[S] + B/[O2] where e represents the concentration of enzyme unit, v the rate of the overall reaction, Vm the maximum velocity, and A and B are constants. Furthermore, the reactions of the enzyme with beta-2-thienylalanine (mostly an oxygenase substrate) and L-methionine (an oxidase substrate) were analyzed by the "stopped flow" method. The following scheme for the mechanism of L-phenylalanine oxidase reaction with both substrates is proposed, based on the data obtained. (formula; see text) Where Eox represents the oxidized form of the enzyme unit, EoxS the enzyme unit (oxidized form)-substrate compound, X the purple intermediate with a characteristic broad absorption band around 540 nm, S the substrate and P the product.     

Importance of barrier shape in enzyme-catalyzed reactions. Vibrationally assisted hydrogen tunneling in tryptophan tryptophylquinone-dependent amine dehydrogenases

C-H bond breakage by tryptophan tryptophylquinone (TTQ)-dependent methylamine dehydrogenase (MADH) occurs by vibrationally assisted tunneling (Basran, J., Sutcliffe, M. J., and Scrutton, N. S. (1999) Biochemistry 38, 3218--3222). We show here a similar mechanism in TTQ-dependent aromatic amine dehydrogenase (AADH). The rate of TTQ reduction by dopamine in AADH has a large, temperature independent kinetic isotope effect (KIE = 12.9 +/- 0.2), which is highly suggestive of vibrationally assisted tunneling. H-transfer is compromised with benzylamine as substrate and the KIE is deflated (4.8 +/- 0.2). The KIE is temperature-independent, but reaction rates are strongly dependent on temperature. With tryptamine as substrate reaction rates can be determined only at low temperature as C-H bond cleavage is rapid, and an exceptionally large KIE (54.7 +/- 1.0) is observed. Studies with deuterated tryptamine suggest vibrationally assisted tunneling is the mechanism of deuterium and, by inference, hydrogen transfer. Bond cleavage by MADH using a slow substrate (ethanolamine) occurs with an inflated KIE (14.7 +/- 0.2 at 25 degrees C). The KIE is temperature-dependent, consistent with differential tunneling of protium and deuterium. Our observations illustrate the different modes of H-transfer in MADH and AADH with fast and slow substrates and highlight the importance of barrier shape in determining reaction rate.     

Redox centers of 4-hydroxybenzoyl-CoA reductase, a member of the xanthine oxidase family of molybdenum-containing enzymes

4-Hydroxybenzoyl-CoA reductase (4-HBCR) is a key enzyme in the anaerobic metabolism of phenolic compounds. It catalyzes the reductive removal of the hydroxyl group from the aromatic ring yielding benzoyl-CoA and water. The subunit architecture, amino acid sequence, and the cofactor/metal content indicate that it belongs to the xanthine oxidase (XO) family of molybdenum cofactor-containing enzymes. 4-HBCR is an unusual XO family member as it catalyzes the irreversible reduction of a CoA-thioester substrate. A radical mechanism has been proposed for the enzymatic removal of phenolic hydroxyl groups. In this work we studied the spectroscopic and electrochemical properties of 4-HBCR by EPR and M?ssbauer spectroscopy and identified the pterin cofactor as molybdopterin mononucleotide. In addition to two different [2Fe-2S] clusters, one FAD and one molybdenum species per monomer, we also identified a [4Fe-4S] cluster/monomer, which is unique among members of the XO family. The reduced [4Fe-4S] cluster interacted magnetically with the Mo(V) species, suggesting that the centers are in close proximity, (<15 A apart). Additionally, reduction of the [4Fe-4S] cluster resulted in a loss of the EPR signals of the [2Fe-2S] clusters probably because of magnetic interactions between the Fe-S clusters as evidenced in power saturation studies. The Mo(V) EPR signals of 4-HBCR were typical for XO family members. Under steady-state conditions of substrate reduction, in the presence of excess dithionite, the [4Fe-4S] clusters were in the fully oxidized state while the [2Fe-2S] clusters remained reduced. The redox potentials of the redox cofactors were determined to be: [2Fe-2S](+1/+2) I, -205 mV; [2Fe-2S] (+1/+2) II, -255 mV; FAD/FADH( small middle dot)/FADH, -250 mV/-470 mV; [4Fe-4S](+1/+2), -465 mV and Mo(VI)/(V)/(VI), -380 mV/-500 mV. A catalytic cycle is proposed that takes into account the common properties of molybdenum cofactor enzymes and the special one-electron chemistry of dehydroxylation of phenolic compounds.     

Electron-transfer reactions of the reductase component of soluble methane monooxygenase from Methylococcus capsulatus (Bath).

Soluble methane monooxygenase (sMMO) catalyzes the hydroxylation of methane by dioxygen to afford methanol and water, the first step of carbon assimilation in methanotrophic bacteria. This enzyme comprises three protein components: a hydroxylase (MMOH) that contains a dinuclear nonheme iron active site; a reductase (MMOR) that facilitates electron transfer from NADH to the diiron site of MMOH; and a coupling protein (MMOB). MMOR uses a noncovalently bound FAD cofactor and a [2Fe-2S] cluster to mediate electron transfer. The gene encoding MMOR was cloned from Methylococcus capsulatus (Bath) and expressed in Escherichia coli in high yield. Purified recombinant MMOR was indistinguishable from the native protein in all aspects examined, including activity, mass, cofactor content, and EPR spectrum of the [2Fe-2S] cluster. Redox potentials for the FAD and [2Fe-2S] cofactors, determined by reductive titrations in the presence of indicator dyes, are FAD(ox/sq), -176 +/- 7 mV; FAD(sq/hq), -266 +/- 15 mV; and [2Fe-2S](ox/red), -209 +/- 14 mV. The midpoint potentials of MMOR are not altered by the addition of MMOH, MMOB, or both MMOH and MMOB. The reaction of MMOR with NADH was investigated by stopped-flow UV-visible spectroscopy, and the kinetic and spectral properties of intermediates are described. The effects of pH on the redox properties of MMOR are described and exploited in pH jump kinetic studies to measure the rate constant of 130 +/- 17 s(-)(1) for electron transfer between the FAD and [2Fe-2S] cofactors in two-electron-reduced MMOR. The thermodynamic and kinetic parameters determined significantly extend our understanding of the sMMO system.     

Determination of the midpoint potential of the FAD and FMN flavin cofactors and of the 3Fe-4S cluster of glutamate synthase

Glutamate synthase is a complex iron-sulfur flavoprotein that catalyzes the reductive transfer of the L-glutamine amide group to C(2) of 2-oxoglutarate, forming two molecules of L-glutamate. The bacterial enzyme is an alphabeta protomer, which contains one FAD (on the beta subunit, approximately 50 kDa), one FMN (on the alpha subunit, approximately 150 kDa), and three different Fe-S clusters (one 3Fe-4S center on the alpha subunit and two 4Fe-4S clusters at an unknown location). To address the problem of the intramolecular electron pathway, we have measured the midpoint potential values of the flavin cofactors and of the 3Fe-4S cluster of glutamate synthase in the isolated alpha and beta subunits and in the alphabeta holoenzyme. No detectable amounts of flavin semiquinones were observed during reductive titrations of the enzyme, indicating that the midpoint potential value of each flavin(ox)/flavin(sq) couple is, in all cases, significantly more negative than that of the corresponding flavin(sq)/flavin(hq) couple. Association of the two subunits to form the alphabeta protomer does not alter significantly the midpoint potential value of the FMN cofactor and of the 3Fe-4S cluster (approximately -240 and -270 mV, respectively), but it makes that of FAD some 40 mV less negative (approximately -340 mV for the beta subunit and -300 mV for FAD bound to the holoenzyme). Binding of the nonreducible NADP(+) analogue, 3-aminopyridine adenine dinucleotide phosphate, made the measured midpoint potential value of the FAD cofactor approximately 30-40 mV less negative in the isolated beta subunit, but had no effect on the redox properties of the alphabeta holoenzyme. This result correlates with the formation of a stable charge-transfer complex between the reduced flavin and the oxidized pyridine nucleotide in the isolated beta subunit, but not in the alphabeta holoenzyme. Binding of L-methionine sulfone, a glutamine analogue, had no significant effect on the redox properties of the enzyme cofactors. On the contrary, 2-oxoglutarate made the measured midpoint potential value of the 3Fe-4S cluster approximately 20 mV more negative in the isolated alpha subunit, but up to 100 mV less negative in the alphabeta holoenzyme as compared to the values of the corresponding free enzyme forms. These findings are consistent with electron transfer from the entry site (FAD) to the exit site (FMN) through the 3Fe-4S center of the enzyme and the involvement of at least one of the two low-potential 4Fe-4S centers, which are present in the glutamate synthase holoenzyme, but not in the isolated subunits. Furthermore, the data demonstrate a specific role of 2-oxoglutarate in promoting electron transfer from FAD to the 3Fe-4S cluster of the glutamate synthase holoenzyme. The modulatory role of 2-oxoglutarate is indeed consistent with the recently determined three-dimensional structure of the glutamate synthase alpha subunit, in which several polypeptide stretches are suitably positioned to mediate communication between substrate binding sites and the enzyme redox centers (FMN and the 3Fe-4S cluster) to tightly control and coordinate the individual reaction steps [Binda, C., et al. (2000) Structure 8, 1299-1308].     

Enzymatic H-transfer requires vibration-driven extreme tunneling

Enzymatic breakage of the substrate C-H bond by Methylophilus methyltrophus (sp. W3A1) methylamine dehydrogenase (MADH) has been studied by stopped-flow spectroscopy. The rate of reduction of the tryptophan tryptophylquinone (TTQ) cofactor has a large kinetic isotope effect (KIE = 16.8 +/- 0.5), and the KIE is independent of temperature. Analysis of the temperature dependence of C-H bond breakage revealed that extreme (ground state) quantum tunneling is responsible for the transfer of the hydrogen nucleus. Reaction rates are strongly dependent on temperature, indicating thermally induced, vibrational motion drives the H-transfer reaction. The data provide direct experimental evidence for enzymatic bond breakage by extreme tunneling driven by vibrational motion of the protein scaffold. The results demonstrate that classical transition state theory and its tunneling derivatives do not adequately describe this enzymatic reaction.     

Autoflavinylation of apo6-hydroxy-D-nicotine oxidase

6-Hydroxy-D-nicotine oxidase (6-HDNO) was expressed in Escherichia coli JM109 cells from the recombinant plasmid pAX-6-HDNO as a beta-galactosidase-6-HDNO fusion protein. Affinity chromatography of the fusion protein on p-aminobenzyl-1-thio-beta-galactopyranoside-agarose and subsequent digestion with protease Xa yielded highly purified apo6-HDNO. Incubation of the purified protein with [14C]FAD demonstrated that flavinylation of apo6-HDNO proceeds autocatalytically. Phosphorylated three-carbon compounds such as glycerol-3-P, which are known to stimulate the formation of the histidyl (N3)-(8 alpha) FAD between apo6-HDNO and FAD (Brandsch, R., and Bichler, V. (1989) Eur. J. Biochem. 182, 125-128), could be replaced in their action by high concentrations of glycerol (45%) or sucrose (20%). These substances apparently induced and stabilized a conformational state of the apoenzyme compatible with covalent attachment of FAD. In the absence of glycerol the apoenzyme readily lost the ability to form holoenzyme at temperatures above 30 degrees C. Holoenzyme formation protected the 6-HDNO polypeptide from this thermal denaturation. Autoflavinylation of 6-HDNO was inhibited by the sulfhydryl reagents dithionitrobenzoate or N-ethylmaleimide. Inhibition was prevented by mercaptoethanol or FAD, but not 6-hydroxy-D-nicotine, the substrate of the holoenzyme. A cysteine-thiol group may therefore be involved in reactions leading to the covalent attachment of FAD to apo6-HDNO. When flavinylation of apo6-HDNO proceeded under anaerobic conditions, the amount of incorporation of [14C]FAD into the polypeptide was indistinguishable from reactions performed in the presence of O2. None of the FAD-derivatives (8-demethyl-FAD, 8-chloro-FAD, and 5-deaza-FAD) could replace FAD in holoenzyme formation. The failure of covalent attachment of 5-deaza-FAD to apo6-HDNO is in agreement with the assumption that the quinone methide form of the isolloxazine ring is an intermediate in the flavinylation reaction.     

Structure-activity relationships in the oxidation of para-substituted benzylamine analogues by recombinant human liver monoamine oxidase A.

Monoamine oxidase A (MAO A) plays a central role in the oxidation of amine neurotransmitters. To investigate the structure and mechanism of this enzyme, recombinant human liver MAO A was expressed and purified from Saccharomyces cerevisiae. Anaerobic titrations of the enzyme require only 1 mol of substrate per mole of enzyme-bound flavin for complete reduction. This demonstrates that only one redox-active group (i.e., the covalent FAD cofactor) is involved in catalysis. The reaction rates and binding affinities of 17 para-substituted benzylamine analogues with purified MAO A were determined by steady state and stopped flow kinetic experiments. For each substrate analogue that was tested, the rates of steady state turnover (k(cat)) and anaerobic flavin reduction (k(red)) are similar in value. Deuterium kinetic isotope effects on k(cat), k(red), k(cat)/K(m), and k(red)/K(s) with alpha, alpha-[(2)H]benzylamines are similar for each substrate analogue that was tested and range in value from 6 to 13, indicating that alpha-C-H bond cleavage is rate-limiting in catalysis. Substrate analogue dissociation constants determined from reductive half-reaction experiments as well as from steady state kinetic isotope effect data [Klinman, J. P., and Matthews, R. G. (1985) J. Am. Chem. Soc. 107, 1058-1060] are in excellent agreement. Quantitative structure-activity relationship (QSAR) analysis of dissociation constants shows that the binding of para-substituted benzylamine analogues to MAO A is best correlated with the van der Waals volume of the substituent, with larger substituents binding most tightly. The rate of para-substituted benzylamine analogue oxidation and/or substrate analogue-dependent flavin reduction is best correlated with substituent electronic effects (sigma). Separation of the electronic substituent parameter (sigma) into field-inductive and resonance effects provides a more comprehensive treatment of the electronic correlations. The positive correlation of rate with sigma (rho approximately 2.0) suggests negative charge development at the benzyl carbon position occurs and supports proton abstraction as the mode of alpha-C-H bond cleavage. These results are discussed in terms of several mechanisms proposed for MAO catalysis and with previous structure-activity studies published with bovine liver MAO B [Walker, M. C., and Edmondson, D. E. (1994) Biochemistry 33, 7088-7098].     

Catalytic reaction profile for alcohol oxidation by galactose oxidase

Galactose oxidase is a remarkable enzyme containing a metalloradical redox cofactor capable of oxidizing a variety of primary alcohols during enzyme turnover. Recent studies using 1-O-methyl alpha-D-galactopyranoside have revealed an unusually large kinetic isotope effect (KIE) for oxidation of the alpha-deuterated alcohol (kH/kD = 22), demonstrating that cleavage of the 6,6'-di[2H]hydroxymethylene C-H bond is fully rate-limiting for oxidation of the canonical substrate. This step is believed to involve hydrogen atom transfer to the tyrosyl phenoxyl in a radical redox mechanism for catalysis [Whittaker, M. M., Ballou, D. P., and Whittaker, J. W. (1998) Biochemistry 37, 8426-8436]. In the work presented here, the enzyme's unusually broad substrate specificity has allowed us to extend these investigations to a homologous series of benzyl alcohol derivatives, in which remote (meta or para) substituents are used to systematically perturb the properties of the hydroxyl group undergoing oxidation. Quantitative structure-activity relationship (QSAR) correlations over the steady state rate data reveal a shift in the character of the transition state for substrate oxidation over this series, reflected in a change in the magnitude of the observed KIE for these reactions. The observed KIE values have been shown to obey a log-linear correlation over the substituent parameter, Hammett sigma. For the relatively difficult to oxidize nitro derivative, the KIE is large (kH/kD = 12.3), implying rate-limiting C-H bond cleavage for the oxidation reaction. This contribution becomes less important for more easily oxidized substrates (e.g., methoxy derivatives) where a much smaller KIE is observed (kH/kD = 3.6). Conversely, the solvent deuterium KIE is vanishingly small for 4-nitrobenzyl alcohol, but becomes significant for the 4-methoxy derivative (kH2O/kD2O = 1.2). These experiments have allowed us to develop a reaction profile for substrate oxidation by galactose oxidase, consisting of three components (hydroxylic proton transfer, electron transfer, and hydrogen atom transfer) comprising a single-step proton-coupled electron transfer mechanism. Each component exhibits a distinct substituent and isotope sensitivity, allowing them to be identified kinetically. The proton transfer component is unique in being sensitive to the isotopic character of the solvent (H2O or D2O), while hydrogen atom transfer (C-H bond cleavage) is independent of solvent composition but is sensitive to substrate labeling. In contrast, electron transfer processes will in general be less sensitive to isotopic substitution. Our results support a mechanism in which initial proton abstraction from a coordinated substrate activates the alcohol toward inner sphere electron transfer to the Cu(II) metal center in an unfavorable redox equilibrium, forming an alkoxy radical which undergoes hydrogen atom abstraction by the tyrosine-cysteine phenoxyl free radical ligand to form the product aldehyde.     

Enzymatic determination of L-phenylalanine and phenylpyruvate with L-phenylalanine dehydrogenase

An enzymatic method is described for the determination of L-phenylalanine or phenylpyruvate using L-phenylalanine dehydrogenase. The enzyme catalyzes the NAD-dependent oxidative deamination of L-phenylalanine or the reductive amination of the 2-oxoacid, respectively. The stoichiometric coupling of the coenzyme allows a direct spectrophotometric assay of the substrate concentration. The equilibrium of the reaction favors L-phenylalanine formation; however, by measuring initial reaction velocities, the enzyme can be used for L-phenylalanine determination, too. Standard solutions of L-phenylalanine in the range of 10-300 microM and of phenylpyruvate (5-100 microM) show a linearity between the value for dENADH/min and the substrate concentration. Besides phenylalanine, the enzyme can convert tyrosine and methionine, and their oxoacids, respectively. The Km values of these substrates are higher. The influence of tyrosine on the determination of phenylalanine was studied and appeared tolerable for certain applications.     

L-[2,5-H2]phenylalanine, an alternate substrate for rat liver phenylalanine hydroxylase

The phenylalanine analogue L-[2,5-H2]phenylalanine (1) was found to be a viable substrate (KM = 0.45 mM, kcat = 8 s-1) for L-phenylalanine-activated, rat liver phenylalanine hydroxylase (EC 1.14.16.1) (PAH). The PAH-catalyzed oxidation of 1 was stoichiometric with the oxidation of cofactor, 6-methyl-tetrahydropterin. Spectral and chromatographic data of the product from the oxidation of 1 by PAH were found to be in accord with a 3,4-epoxide. The enzymatic epoxidation of 1 is consistent with the hypothesis of an intermediate arene oxide on the reaction coordinate for PAH hydroxylation of L-phenylalanine.     

Use of 8-substituted-FAD analogues to investigate the hydroxylation mechanism of the flavoprotein 2-methyl-3-hydroxypyridine-5-carboxylic acid oxygenase

2-Methyl-3-hydroxypyridine-5-carboxylic acid (MHPC) oxygenase (MHPCO) is a flavoprotein that catalyzes the oxygenation of MHPC to form alpha-(N-acetylaminomethylene)-succinic acid. Although formally similar to the oxygenation reactions catalyzed by phenol hydroxylases, MHPCO catalyzes the oxygenation of a pyridyl derivative rather than a simple phenol. Therefore, in this study, the mechanism of the reaction was investigated by replacing the natural cofactor FAD with FAD analogues having various substituents (-Cl, -CN, -NH(2), -OCH(3)) at the C8-position of the isoalloxazine. Thermodynamic and catalytic properties of the reconstituted enzyme were investigated and found to be similar to those of the native enzyme, validating that these FAD analogues are reasonable to be used as mechanistic probes. Dissociation constants for the binding of MHPC or the substrate analogue 5-hydroxynicotinate (5HN) to the reconstituted enzymes indicate that the reconstituted enzymes bind well with ligands. Redox potential values of the reconstituted enzymes were measured and found to be more positive than the values of free FAD analogues, which correlated well with the electronic effects of the 8-substituents. Studies of the reductive half-reaction of MHPCO have shown that the rates of flavin reduction by NADH could be described as a parabolic relationship with the redox potential values of the reconstituted enzymes, which is consistent with the Marcus electron transfer theory. Studies of the oxidative half-reaction of MHPCO revealed that the rate of hydroxylation depended upon the different analogues employed. The rate constants for the hydroxylation step correlated with the calculated pK(a) values of the 8-substituted C(4a)-hydroxyflavin intermediates, which are the leaving groups in the oxygen transfer step. It was observed that the rates of hydroxylation were greater when the pK(a) values of C(4a)-hydroxyflavins were lower. Although these results are not as dramatic as those from analogous studies with parahydroxybenzoate hydroxylase (Ortiz-Maldonado et al., (1999) Biochemistry 38, 8124-8137), they are consistent with the model that the oxygenation reaction of MHPCO occurs via an electrophilic aromatic substitution mechanism analogous to the mechanisms for parahydroxybenzoate and phenol hydroxylases.     

Radioenzymatic assay for reductive catalysis of N(5)N(10)-methylenetetrahydrofolate by methylenetetrahydrofolate reductase

Methylenetetrahydrofolate reductase catalyzes the reduction of N(5), N(10)-methylenetetrahydrofolate to N(5)-methyltetrahydrofolate. Because this substrate is unstable and dissociates spontaneously into formaldehyde and tetrahydrofolate, the customary method to assay the catalytic activity of this enzyme has been to measure the oxidation of [14C]N(5)-methyltetrahydrofolate to N(5), N(10)-methylenetetrahydrofolate and quantify the [14C]formaldehyde that dissociates from this product. This report describes a very sensitive radioenzymatic assay that measures directly the reductive catalysis of N(5),N(10)-methylenetetrahydrofolate. The radio-labeled substrate, [14C]N(5),N(10)-methylenetetrahydrofolate, is prepared by condensation of [C(14)]formaldehyde with tetrahydrofolate and the stability of this substrate is maintained for several months by storage at -80 degrees C in a pH 9.5 buffer. Partially purified methylenetetrahydrofolate reductase from rat liver, incubated with the radio-labeled substrate and the cofactors, NADPH and FAD at pH 7. 5, generates [14C]N(5)-methyltetrahydrofolate, which is stable and partitions into the aqueous phase after the assay is terminated with dimedone and toluene. A K(m) value of 8.2 microM was obtained under conditions of increasing substrate concentration to ensure saturation kinetics. This method is simple, very sensitive and measures directly the reduction of N(5), N(10)-methylenetetrahydrofolate to N(5)-methyltetrahydrofolate, which is the physiologic catalytic pathway for methylenetetrahydrofolate reductase.     

6-S-cysteinylation of bi-covalently attached FAD in berberine bridge enzyme tunes the redox potential for optimal activity

A mutagenic analysis of the amino acid residues His-104 and Cys-166, which are involved in the bi-covalent attachment of FAD to berberine bridge enzyme, was performed. Here we present a detailed biochemical characterization of the cysteine link to FAD observed in this recently discovered group of flavoproteins. The C166A mutant protein still has residual activity, but reduced to approximately 6% of the turnover rate observed for wild-type berberine bridge enzyme. A more detailed analysis of single reaction steps by stopped-flow spectrophotometry showed that the reductive half-reaction is greatly influenced by the lack of the 6-S-cysteinyl linkage, resulting in a 370-fold decrease in the rate of flavin reduction. Determination of the redox potentials for both wild type and the C166A mutein revealed that the difference in the redox potential observed can fully account for the change in the kinetic properties. The wild-type protein exhibits a midpoint potential of +132 mV, which is the highest redox potential determined for any flavoenzyme so far. Removal of the cysteine linkage to FAD in the C166A mutein leads to a redox potential of +53 mV, which is in the expected range for flavoproteins with a single covalent attachment of FAD to a His residue via its 8-alpha position. We also show that the biochemical properties of the mutein resemble that of typical flavoprotein oxidases and that deviations from this behavior observed for the wild type are due to the FAD-6-S-cysteinyl bond. In addition, rapid reaction stopped-flow experiments give no indication for a radical mechanism supporting the direct transfer of a hydride from the substrate to the cofactor.     

Detection of CMP-N-acetylneuraminic acid hydroxylase activity in fractionated mouse liver.

The finding that N-glycoloylneuraminic acid (Neu5Gc) in pig submandibular gland is synthesized by hydroxylation of the sugar nucleotide CMP-Neu5Ac [Shaw & Schauer (1988) Biol. Chem. Hoppe-Seyler 369, 477-486] prompted us to investigate further the biosynthesis of this sialic acid in mouse liver. Free [14C]Neu5Ac, CMP-[14C]Neu5Ac and [14C]Neu5Ac glycosidically bound by Gal alpha 2-3- and Gal alpha 2-6-GlcNAc beta 1-4 linkages to fetuin were employed as potential substrates in experiments with fractionated mouse liver homogenates. The only substrate to be hydroxylated was the CMP-Neu5Ac glycoside. The product of the reaction was identified by chemical and enzymic methods as CMP-Neu5Gc. All of the CMP-Neu5Ac hydroxylase activity was detected in the high-speed supernatant fraction. The hydroxylase required a reduced nicotinamide nucleotide [NAD(P)H] coenzyme and molecular oxygen for activity. Furthermore, the activity of this enzyme was enhanced by exogenously added Fe2+ or Fe3+ ions, all other metal salts tested having a negligible or inhibitory influence. This hydroxylase is therefore tentatively classified as a monooxygenase. The cofactor requirement and CMP-Neu5Ac substrate specificity are identical to those of the enzyme in high-speed supernatants of pig submandibular gland, suggesting that this is a common route of Neu5Gc biosynthesis. The relevance of these results to the regulation of Neu5Gc expression in sialoglycoconjugates is discussed.     

Oxidative Stress at High Temperatures in Lactococcus lactis Due to an Insufficient Supply of Riboflavin

Lactococcus lactis MG1363 was found to be unable to grow at temperatures above 37°C in a defined medium without riboflavin, and the cause was identified to be dissolved oxygen introduced during preparation of the medium. At 30°C, growth was unaffected by dissolved oxygen and oxygen was consumed quickly. Raising the temperature to 37°C resulted in severe growth inhibition and only slow removal of dissolved oxygen. Under these conditions, an abnormally low intracellular ratio of [ATP] to [ADP] (1.4) was found (normally around 5), which indicates that the cells are energy limited. By adding riboflavin to the medium, it was possible to improve growth and oxygen consumption at 37°C, and this also normalized the [ATP]-to-[ADP] ratio. A codon-optimized redox-sensitive green fluorescent protein (GFP) was introduced into L. lactis and revealed a more oxidized cytoplasm at 37°C than at 30°C. These results indicate that L. lactis suffers from heat-induced oxidative stress at increased temperatures. A decrease in intracellular flavin adenine dinucleotide (FAD), which is derived from riboflavin, was observed with increasing growth temperature, but the presence of riboflavin made the decrease smaller. The drop was accompanied by a decrease in NADH oxidase and pyruvate dehydrogenase activities, both of which depend on FAD as a cofactor. By overexpressing the riboflavin transporter, it was possible to improve FAD biosynthesis, which resulted in increased NADH oxidase and pyruvate dehydrogenase activities and improved fitness at high temperatures in the presence of oxygen.